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The Bitdefender disassembler

The Bitdefender disassembler (bddisasm) is a lightweight, x86/x64 only instruction decoder. It is easy to integrate, easy to work with, it has no external dependencies, it is thread-safe, it allocates no memory at all, it works in virtually any environment (we use it inside user, kernel, hypervisor, on both Windows and Linux environments), and it provides lots of info regarding the decoded instructions, such as: operands (both explicit and implicit), access mode for each operand, CPUID feature flag, flags access, etc. More examples and info about the project can be found on the official documentation: Bitdefender disassembler

Projects

  1. bddisasm - this is the main disassembler project. In order to use the Bitdefender disassembler, all you have to do is build this project, and link with the output library. The only headers you need are located inside the inc folder.
  2. bdshemu - this project makes use of the main bddisasm lib in order to build a simple, lightweight, fast, instructions emulator, designated to target shellcodes. This project is also integrated inside the disasmtool, so you can emulate raw binary files, and see their output. Note that this simple emulator supports basic x86/x64 instructions, and does not support emulating any kind of API call. In addition, the only supported memory accesses are inside the shellcode itself, and on the emulated stack.
  3. isagenerator_x86 - this project contains the instruction definitions and the scripts required to generate the disassembly tables. If you wish to add support for a new instruction, this is the place. This project will automatically generate several header files (instructions.h, mnemonics.h, constants.h, table_*.h), so please make sure you don't manually edit any of these files. You will need Python 3 to run the generation scripts.
  4. disasmtool - this project is a command line disassembler tool, used mainly as an example of how to integrate the bddisasm and bdshemu libraries.
  5. bindings - bindings for python, and Rust.

Objectives

The main objectives of this disassembler are:

  1. Lightweight - it's written in C, with no external dependencies, no memory allocated, and thread safe by design.
  2. Fast - less than 300 CPU clocks on an Intel Core i7-8650U per decoded instruction (more than 7M instructions per second).
  3. Resilient - tested against internal fuzzers and the famous mishegos tool.
  4. Easy to work with - just include the main header file, bddisasm.h, link with the bddisasm library, and call the NdDecode API!
  5. Complete - support every x86 instruction to date, and provide as much information as possible.

Build and install

Using vcpkg

The easiest way of installing bddisasm is with vcpkg:

vcpkg install bddisasm

This will install bddisasm and bdshemu static libraries.

Note that the version available on vcpkg may not always be the latest.

Using CMake

This is the recommended way of using the library.

Prerequesites:

  • CMake 3.16 or newer (older version may work, but they have not been tested)
  • Ninja (optional, but recommended, especially on Windows)

The build process was tested with GCC and Clang on Linux and MSVC on Windows. Note that the Windows kernel build target is available only when using MSBuild.

To build the project run:

mkdir build
cmake -B build .
cmake --build build

This will build bddisasm, bdshemu, and disasmtool. For skipping the disasmtool build configure CMake with BDD_INCLUDE_TOOL=OFF:

mkdir build
cmake -B build . -DBDD_INCLUDE_TOOL=OFF

To install the project use:

cmake --build build --target install

This will install the bddisasm and bdshemu static libraries and their public headers. If disasmtool was built it will also be installed. Depending on the install location you may need to run the command as root.

Optionally, if a python 3 interpreter is found the instruction tables can be regenerated with:

cmake --build build --target isagenerator

To disable the isagenerator target configure CMake with BDD_INCLUDE_ISAGENERATOR=OFF.

Once installed, CMake projects can use find_package to find the library:

find_package(bddisasm REQUIRED)

Two targets are provided:

  • bddisasm::bddisasm - this should be used for targets that need only the decoder, without the shell code emulator
  • bddisasm::bdshemu - this should be used for targets that need the shell code emulator (note that it will pull in bddisasm::bddisasm automatically)

There is no need to manually set include or link directories, simply use target_link_libraries with the needed target, for example:

find_package(bddisasm REQUIRED)

# decoder-tool needs only the decoder library
target_link_libraries(decoder-tool PRIVATE bddisasm::bddisasm)

# emulator-tool needs bdshemu
target_link_libraries(emulator-tool PRIVATE bddisasm::bdshemu)

nd_vsnprintf_s and nd_memset

By default, if vsnprintf and memset functions are available, the nd_vsnprintf_s and nd_memset functions are implemented directly by bddisasm. To signal this, BDDISASM_HAS_VSNPRINTF and BDDISASM_HAS_MEMSET will be added to the public compile definitions of bddisasm. This can be disabled by configuring CMake with BDD_USE_EXTERNAL_VSNPRINTF=ON and BDD_USE_EXTERNAL_MEMSET=ON.

Using as a sub-project

The project can be consumed as a sub-project, either by adding it as a git submodule, or by using CMake's FetchContent:

With FetchContent:

FetchContent_Declare(
    bddisasm
    GIT_REPOSITORY https://github.com/bitdefender/bddisasm
    GIT_TAG origin/master
)

FetchContent_MakeAvailable(bddisasm)

As a git submodule:

# Assuming the submodule is checked out at external/bddisasm
add_subdirectory(external/bddisasm)

In both cases the bddisasm::bddisasm and bddisasm::bdshemu targets will be provided.

When used as a sub-project the disasmtool, isagenerator, and install targets are not available.

Using Make on Linux

To build the project run make in the root of the repository. This will build only the bddisasm and bdshemu static libraries, without disasmtool.

To install the project run make install. Depending on the install location you may need to run the command as root.

nd_vsnprintf_s and nd_memset will not be defined by bddisasm, integrators must provide these functions.

Using MSBuild on Windows

In order to build the projects on Windows you need:

When you first open bddisasm.sln in Visual Studio should prompt you to install any missing components. This should be enough to build bddisasm, bdshemu, and disasmtool.

For the DebugKernel and ReleaseKernel configurations, WDK 1903 is needed, alongside the Windows Driver Kit Visual Studio extension (the WDK installer should take care of this).

For isagenerator, Python 3 is needed.

Building any of the projects is done directly from Visual Studio.

The results will be in the bin directory in the root of the repository.

nd_vsnprintf_s and nd_memset will not be defined by bddisasm, integrators must provide these functions.

Using pre-compiled binaries

Each release publishes static libraries, as well as the disasmtool CLI tool.

You can verify these artifacts using GitHub Artifact Attestation:

# Verify a component
$ gh attestation verify disasmtool -o bitdefender
# Or the entire bundle
$ gh attestation verify x86-windows-release.zip -o bitdefender

This is not available for bddisasm 2.1.4 or older.

Note that this is currently a beta feature (see Introducing Artifact Attestationsnow in public beta for details).

Decoding x86 instructions

Decoding API

There are 4 decoding functions, but internally, they all do the same, albeit some of them with implicit arguments:

  • NDSTATUS NdDecode(INSTRUX *Instrux, const uint8_t *Code, uint8_t DefCode, uint8_t DefData) - this API should be used only if you don't care about the length of the input buffer;
  • NDSTATUS NdDecodeEx(INSTRUX *Instrux, const uint8_t *Code, size_t Size, uint8_t DefCode, uint8_t DefData); - decode instruction from a buffer with maximum length Size;
  • NDSTATUS NdDecodeEx2(INSTRUX *Instrux, const uint8_t *Code, size_t Size, uint8_t DefCode, uint8_t DefData, uint8_t DefStack, uint8_t PreferedVendor); - decode instructions with a preferred vendor;
  • NDSTATUS NdDecodeWithContext(INSTRUX *Instrux, const uint8_t *Code, size_t Size, ND_CONTEXT *Context); - base decode API; the input parameters - DefCode, DefData, DefStack, VendMode and FeatMode must all be filled in the Context structure before calling this function. The Context structure should also be initialized using NdInitContext before the first decode call.

Note that by default, the default vendor ND_VEND_ANY is used for decoding (which means that bddisasm will try to decode as much as possible). Also, the default features mask is ND_FEAT_ALL, meaning that bddisasm will optimistically try to decode instructions which are mapped onto the wide NOP space as well (for example, MPX or CET). If these parameters must be changed, it is advised to use the NdDecodeWithContext API.

Converting decoded instructions to textual disassembly must be done using the NdToText API. bddisasm only supports Intel, masm-style syntax.

Example

Working with bddisasm is very easy. Decoding and printing the disassembly of an instruction is quick & simple:

#include <stdio.h>
#include "bddisasm/disasmtypes.h"
#include "bddisasm/bddisasm.h"

int nd_vsnprintf_s(
    char *buffer,
    size_t sizeOfBuffer,
    size_t count,
    const char *format,
    va_list argptr
    )
{
    return vsnprintf(buffer, sizeOfBuffer, format, argptr);
}

void* nd_memset(void *s, int c, size_t n)
{
    return memset(s, c, n);
}


int main()
{
    INSTRUX ix;
    uint8_t code[] = { 0x48, 0x8B, 0x48, 0x28 };

    NDSTATUS status = NdDecodeEx(&ix, code, sizeof(code), ND_CODE_64, ND_DATA_64);

    // Check if decoding failed.
    if (!ND_SUCCESS(status))
    {
        printf("Decode failed with error %x!\n", status);
        return -1;
    }

    // Checking if the instruction is a MOV.
    if (ix.Instruction == ND_INS_MOV)
    {
        printf("The instruction is mov!\n");
    }

    // Checking if memory is read by the instruction.
    if (!!(ix.MemoryAccess & ND_ACCESS_ANY_READ))
    {
        printf("The instruction reads memory!\n");
    }

    // Checking if the destination is the RCX register.
    if (ND_IS_OP_REG(&ix.Operands[0], ND_REG_GPR, 8, NDR_RCX))
    {
        printf("The first op is RCX!\n");
    }

    // Checking if the source is memory.
    if (ix.Operands[1].Type == ND_OP_MEM)
    {
        printf("Source is memory!\n");

        if (ix.Operands[1].Info.Memory.HasSeg)
        {
            printf("    Segment reg: %d\n", ix.Operands[1].Info.Memory.Seg);
        }

        if (ix.Operands[1].Info.Memory.HasBase)
        {
            printf("    Base reg: %d\n", ix.Operands[1].Info.Memory.Base);
        }

        if (ix.Operands[1].Info.Memory.HasIndex)
        {
            printf("    Index reg: %d, scale: %d\n", ix.Operands[1].Info.Memory.Index, ix.Operands[1].Info.Memory.Scale);
        }

        if (ix.Operands[1].Info.Memory.HasDisp)
        {
            printf("    Displacement: 0x%llx\n", ix.Operands[1].Info.Memory.Disp);
        }
    }

    // Create the text disassembly for this instruction.
    char text[ND_MIN_BUF_SIZE];

    NdToText(&ix, 0, sizeof(text), text);

    printf("Instruction: %s\n", text);

    return 0;
}

Working with the extended API is also trivial:

    INSTRUX ix;
    ND_CONTEXT ctx;
    uint8_t code[] = { 0x48, 0x8B, 0x48, 0x28 };

    // This has to be done only once.
    NdInitContext(&ctx);

    ctx.DefCode = ND_CODE_64;
    ctx.DefData = ND_DATA_64;
    ctx.DefStack = ND_STACK_64;
    ctx.VendMode = ND_VEND_ANY;
    ctx.FeatMode = ND_FEAT_ALL; // Use ND_FEAT_NONE, if you wish to see NOPs instead of MPX/CET/CLDEMOTE instructions.

    // From here one, the ctx can be reused for any number of NdDecodeWithContext calls.
    NDSTATUS status = NdDecodeWithContext(&ix, code, sizeof(code), &ctx);
    ...

Credits

The entire Bitdefender HVI team.